Brain-stimulation and cortical plasticity

Research Area

Neurophysiology and Brainstimulation

Researchers

Vishnudev Ramachandra; Martin A. Giese; Alia Benali;

Collaborators

Cornelius Schwarz; Ulf Ziemann; Klaus Funke; Bingshuo Li; Axel Oeltermann; Friederike Pfeiffer; Ken-Ichiro Tsutsui

Description

In the past, methods such as brain stimulation were used to understand the brain and its functions. Later it was found that brain stimulation can also lead to changes in the brain functions and trigger plasticity, a potential of the brain to react to new environmental conditions. Therefore, brain stimulation is currently used to treat cortical dysfunction, which is the basis for neurological and neuropsychiatric disorders ranging from Parkinson's disease to obsessive-compulsive disorder, anxiety, depression and addiction.

Our group aims to study and understand the mechanisms and circuits triggered by brain stimulation. In particular, we study the mechanisms of non-invasive interventions of transcranial magnetic stimulation (TMS) and invasive interventions of intracortical micro-stimulation, which are used to promote the reorganization and repair of neuronal circuits.

Our team uses electrical recordings to study the activated circuits.  A major problem we face is in detecting a small electrical signal below a strong magnetic/electrical field; a task that cannot use standard electrophysiological devices. Therefore, we developed new recording systems that allow us to record neuronal activity with minimal data loss around the stimulation period. In our group we pursue several approaches:

  • Further development of electrophysiological recording systems (Ramachandra, Li and Benali, Schwarz in cooperation with Axel Oeltermann)
  • Probing the neuropysiological effect of TMS (Benali, Ramachandra, Li, Giese,   Ziemann & Schwarz)
  • Novel analysis techniques using machine-learning approaches for removal of TMS induced artifact (Ramachandra, Benali and Giese)

 

This project has received funding from the DFG GZ: BE 6084/2-1.

 

Publications

Pfeiffer, F. & Benali, A. (2020). Could non-invasive brain-stimulation prevent neuronal degeneration upon ion channel re-distribution and ion accumulation after demyelination?. Neural Regeneration Research, 15(11), 1977-1980.
Could non-invasive brain-stimulation prevent neuronal degeneration upon ion channel re-distribution and ion accumulation after demyelination?
Abstract:

Fast and efficient transmission of electrical signals in the nervous system is mediated through myelinated nerve fibers. In neuronal diseases such as multiple sclerosis, the conduction properties of axons are disturbed by the removal of the myelin sheath, leaving nerve cells at a higher risk of degenerating. In some cases, the protective myelin sheath of axons can be rebuilt by remyelination through oligodendroglial cells. In any case, however, changes in the ion channel organization occur and may help to restore impulse conduction after demyelination. On the other hand, changes in ion channel distribution may increase the energy demand of axons, thereby increasing the probability of axonal degeneration. Many attempts have been made or discussed in recent years to increase remyelination of affected axons in demyelinating diseases such as multiple sclerosis. These approaches range from pharmacological treatments that reduce inflammatory processes or block ion channels to the modulation of neuronal activity through electrical cortical stimulation. However, these treatments either affect the entire organism (pharmacological) or exert a very local effect (electrodes). Current results show that neuronal activity is a strong regulator of oligodendroglial development. To bridge the gap between global and very local treatments, non-invasive transcranial magnetic stimulation could be considered. Transcranial magnetic stimulation is externally applied to brain areas and experiments with repetitive transcranial magnetic stimulation show that the neuronal activity can be modulated depending on the stimulation parameters in both humans and animals. In this review, we discuss the possibilities of influencing ion channel distribution and increasing neuronal activity by transcranial magnetic stimulation as well as the effect of this modulation on oligodendroglial cells and their capacity to remyelinate previously demyelinated axons. Although the physiological mechanisms underlying the effects of transcranial magnetic stimulation clearly need further investigations, repetitive transcranial magnetic stimulation may be a promising approach for non-invasive neuronal modulation aiming at enhancing remyelination and thus reducing neurodegeneration

Authors: F. Pfeiffer Alia Benali
Type of Publication: Article
Journal: Neural Regeneration Research
Volume: 15
Number: 11
Pages: 1977-1980
Year: 2020
Full text: PDF | Online version
[Bibtex]
Li, B., Virtanen, J. P., Oeltermann, A., Schwarz, C., Giese, M. A., Ziemann, U. et al. (2017). Lifting the Veil on the Dynamics of Neuronal Activities Evoked by Transcranial Magnetic Stimulation. eLife pii: e30552.
Lifting the Veil on the Dynamics of Neuronal Activities Evoked by Transcranial Magnetic Stimulation
Authors: Bin Li Jan Paul Virtanen Anton Oeltermann Con Schwarz Martin A. Giese; U Ziemann Alia Benali
Type of Publication: Article
Full text: PDF | Online version
[Bibtex]

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